Roll-forming machine for gutter cap and method for making same

ABSTRACT

A novel roll-forming machine is disclosed for making caps to cover rain gutters and prevent the entry of debris into the rain gutters that cause damming and overflow. The roll-forming machine may be used in a predetermined manner to manufacture caps of different profiles in substantially any desired length, thus substantially reducing the number of joints between adjacent sections and increasing the amount of water run-off captured within the rain gutters. Also disclosed is a unique rain gutter cap profile substantially complementing the generally angular design of standard rain gutters while still maximizing the redirection of water into the underlying rain gutter while keeping potentially clogging debris from entering the rain gutter.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority from U.S. Provisional Patent Application filed Jul. 1, 2004 and assigned application Ser. No. 60/584,932, the contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to devices for diverting water from a surface and particularly to a unique device for reducing the amount of detritus allowed to fill a rain gutter while maximizing the diversion of water into the gutter. This invention also relates to a method and apparatus for manufacturing such a device as well as a unique gutter cap configuration.

2. Discussion of the Related Art

Gutters are mounted to the drip edges of houses and other structures to capture water runoff from the roof structures and divert the water to predetermined locations. These traditional structures consist of a trough attached to the fascia board or similar structure adjacent the drip edge of the roof so as to collect the runoff from the overlying surface. The water collected in the trough flows down gradient to a downspout where it is collected, or dispersed onto the ground. The efficiency of rain gutters is substantially hampered by the amount of debris and detritus within the troughs. In particular, leaves, branches, and the like entrained within the runoff are captured within the trough and act as a dam to the flow of water to the downspout.

To alleviate the capture of unwanted debris, wire mesh was used to capture the debris. The debris accumulating along the wire mesh would then present an emergent obstacle that would divert water runoff at angles that often overshot the trough. Over time, the debris field on top of the wire mesh often caused a collapse of the mesh such that the debris ultimately dammed the water flow to the drain pipe.

Later designs to keep debris from entering the gutters included the use of a solid sheet of metal or plastic material that substantially covered the rain gutter. The outer edge of the sheet included a predetermined radius intended to direct the water runoff into the trough using the physical properties of adhesion. The adhesion coefficient for debris was much lower resulting in the debris being swept off the end and onto the ground below. However, depending upon the amount of rainfall, the radius of curvature was too great, resulting in water cascading off of the radius curve and falling onto the ground, essentially defeating the purpose of the gutter guard in the first place.

Another disadvantage with gutter cap systems is that they are precut into fixed lengths. At times, these precut lengths are insufficient to span the entire distance of a single run, resulting in the need to splice and overlap joints. Coefficients of expansion and contraction also influenced these caps, causing the caps to become dislodged and unsightly.

SUMMARY OF THE INVENTION

It is an object of the instant invention to substantially increase the flow of water from a gutter cap into an underlying gutter trough.

It is another object of the instant invention to produce a gutter cap that can be formed from a continuous length of metal without the need for creating spices, butt-joints or overlapping joints.

In another form of the invention, a unique machine is devised for manufacturing gutter caps that carryout the foregoing objects.

According to another form of the invention, a gutter cap is provided having a gently sloped upper surface positioned beneath the roofing surface of the building or other structure. Spaced along the sloped upper surface may be one or more ridges extending along at least a portion of the length of the gutter cap. The gutter cap may also contain one or more rows of perforation up-slope of the ridges to permit the passage of water directly into the underlying gutter trough. Down slope of the ridges or ripples, the gutter cap is radiused such that the terminal end or lower limb of the gutter cap extends at least partially above the trough.

According to another form of the invention, a gutter trough is attached to the fascia board of a building a predetermined distance below the drip edge of the roof. A mounting bracket having a number of stepped segments engages the outer most edge of the gutter to provide structural rigidity for the trough. The opposite end of the mounting bracket engages the opposite surface of the gutter trough. At least one fastener is passed through the mounting bracket and into the underlying fascia board to hold the gutter trough in position.

Another form of the invention includes a flange that is angled and received beneath a downwardly extending flange of a drip edge normally attached to the edge of the roof structure. Away from the angled flange, the gutter cap forms a sloping surface to a point slightly beyond the outer edge of the gutter trough. At that point, the gutter cap is radiused to form a nose. The radius of the nose portion is preferably greater than 0.03125 inch, but may be smaller so long as the degree of the bend does not disturb the substantially smooth texture of the sloped surface to interfere with the flow of water over the surface. The edge of the gutter cap opposite the flange extends back under the sloped surface and terminates above the gutter trough to divert the water into the trough. The terminal end of the gutter cap is retained in position by the mounting bracket used to fix the gutter trough to the building.

In yet another form of the invention, a gutter trough is attached to the fascia board of a structure by a mounting bracket located within the gutter trough. The mounting bracket includes a plurality of step-like structures, one of which engages the outmost edge of the gutter trough. The opposite end of the mounting bracket engages the opposite side of the trough and is adapted to receive at least one downwardly-angled fastener to attach the gutter trough to the fascia. An overlying gutter cap is provided and includes a sloped planar upper-surface designed to be received under the roofing material by a predetermined distance such that runoff from the roofing material flows onto the gutter cap. The opposite edge of the gutter cap is directed back under the sloped surface to form a nose of predetermined profile. The end extending back under the sloped surface terminates above the gutter trough. This edge of the gutter cap terminating above the gutter trough includes a flange that is attached at a predetermined location to the mounting bracket.

In each of the embodiments described above, the flow of the water down the upper surface of the gutter cap is dispersed to generally form a sheet. Because of surface tension (molecular attraction) between the substrate and the water, the water flows substantially evenly over the cap surface. As the water approaches the nose, the adhesion property directs the water around the nose and into the gutter trough. In the embodiments where a water break or flange is provided above the trough, the water impacting the flange is redirected in a spray-like fashion into the trough. This intentional agitation of the runoff water helps keep small particles of detritus in suspension to flow down gradient. Larger debris entrained in the water runoff over the gutter cap is unable to remain in suspension and is forced over the nose and away from the gutter trough, leaving the gutter free of clogging debris.

The advantages of the instant invention include the dispersal effect of the water on the cap surface, increasing the adhesion property of the water to the surface and increasing the amount of water deposited within the trough. Another advantage of the instant invention is the capture of a substantial portion of the water runoff as a result of the water passing into the perforated opening up slope surface of the cascading ridges or ripples. Another advantage of the instant invention is the unique mounting bracket used to mount the gutter trough to the fascia board and its function of anchoring the lower edge of the cap within the trough. The mounting bracket, in combination with the downwardly depending flange of the cap continuously agitates the water, keeping small sediment in suspension as it moves along the trough and down the downspouts. This results in a cleaner trough and improved water flow.

These and other advantages will become readily apparent when taken in combination with the following detailed description and the drawing figures.

BRIEF DESCRIPTION OF THE DRAWING FIGURES

FIG. 1 is an oblique view of one embodiment of a rain gutter cap.

FIG. 2 is a schematic side elevation view of one embodiment of a roll-forming machine for creating the gutter cap shown in FIG. 1.

FIG. 3 is a plan view of the invention shown in FIG. 2.

FIG. 4 is a bottom view of the invention shown in FIG. 2.

FIG. 5 is a section view of the invention taken along line V-V.

FIG. 6 is a section view of the invention taken along line VI-VI.

FIG. 7 is a section view of the invention taken along line VII-VII.

FIG. 8 is a section view of the invention taken along line VIII-VIII.

FIG. 9 is a section view of the invention taken along line IX-IX.

FIG. 10 is a section view of the invention taken along line X-X.

FIG. 11 is a section view of the invention taken along line XI-XI.

FIG. 12 is a section view of the invention taken along line XII-XII.

FIG. 13 is a section view of the invention taken along line XIII-XIII.

FIG. 14 is a section view of the invention taken along line XIV-XIV.

FIG. 15 is a section view of the invention taken along line XV-XV.

FIG. 16 is an oblique view of another embodiment of a gutter cap manufactured according to the method and providing improved capture of water run-off.

FIG. 17 is an oblique view of an alternate embodiment of the gutter assembly.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The instant invention include a novel cap for a rain gutter intended to exclude debris, yet capture water runoff from the roof structures of buildings and the like. In combination with the novel gutter cap is a novel and unique bracket used to mount a rain gutter to a fascia board of the structure. In addition, a unique method and machine are disclosed for making this inventive gutter cap.

FIG. 1 generally illustrates an embodiment of a rain gutter assembly 20 including a rain gutter 22 having a predetermined profile and mounted to a fascia board 24 of a structure or building 26. In this particular case, the rain gutter 22 includes an inside vertical flange 28 integral with a bottom flange 30 extending generally perpendicular there from. Extending upward from the distal edge of the flange 30 is an outer flange 32 often shaped into a decorative profile. In the rain gutter 22 shown, the outer flange 32 terminates with a capture surface 34 inclined in towards the interior of the rain gutter 22. Depending from the inner edge of capture surface 34 is a drip edge 36 angled back towards the outer flange 32. The angling of capture surface 34 and drip edge 36 create a partially enclosed space 38 for reasons that will become readily apparent below. As is conventional in rain gutters, aluminum or plastic may be used to build the gutter trough 22.

Anchoring and fixing the rain gutter 22 to the fascia board 24 are a plurality of stepped mounting-brackets 40. Each mounting bracket 40 includes a lower flange 42 connected by a plurality of webs 44 to a cascading series of stepped flanges 46, each having one end terminating in a vertical wall of an adjacent step, and the other end forming the crest of the subsequent step. As shown in FIG. 1, each step 48 has an upper surface inclined toward the fascia board 24. The first end 50 of each mounting bracket 40 includes at least one inclined port 52 adapted to receive a fastener therein intended to penetrate the flange 28 of the rain gutter and pass into the fascia board 24 to secure the rain gutter 22 in place. The inclined angle provided by port 52 when taken in combination with the angle of the first end 50 provides a preventive measure to keep the gutter from sagging over time. The opposite end 54 of each mounting bracket 40 terminates in a vertical flange 56 which is intended to be received within the space 38 of the rain gutter 22 formed by capture surface 34 of drip edge 36 to support the cantilevered section (outer flange 32) and add strength.

In the embodiment shown in FIG. 1, the gutter cap 22 is intended for use below the drip-edge 62 at the edge of the roof 64. For the sake of simplicity, the plywood underlayment or subsurface features of the roof 64 are omitted from the drawing figures. However, it is generally understood that the drip edge 62 is mounted to the plywood or similar material. Overlying the flange of the drip edge 62 on the roof is typically a felt or similar material. In the case of a composite roof, the felt is followed by a number of courses of fiberglass and asphalt shingles (not shown). In certain instances, the drip edge 62 includes a downwardly depending flange 66 for forcing water away from the joint between the fascia board and the underlayment or roof material.

In situations where a drip edge similar to that designated by numeral 62 is used, the vertical flange 70 is placed between the fascia board 24 and the vertically extending flange 56 of the drip edge 62. In this manner, water received on surface 72 is restricted from flowing onto the fascia board 22. Coupled with the generally downward slope of surface 72, water cascading off of the roof 64 is dispersed over the gutter cap surface and flows away from the fascia board 22. The upper surface 72 of the gutter cap 20 increases in slope and merges into a bull-nose section 74 overlying the outer flange 32 of the rain gutter 22. The radius of the bull-nose section 74 is created by the angular arc between the inwardly directed flange 76 of the cap and the arcuate or planar portion 72. The relative position between the two components is fixed by anchoring a flange 78 (later referred to as a water break flange 78) to the vertical wall of one of the stepped flanges 46 on the mounting bracket 40.

The relative angle between the inward flange 76 and planar-arcuate surface 72 can vary within a range so long as the adhesion properties of the water with the gutter cap surface 72 are maintained. For it is the purpose of this structure to take advantage of the adhesion property of water to the surface 72 to direct the runoff down the surface 72, around the bull-nose section 74 and into the gutter trough 22. Debris over a preferred size and mass lacks the adhesion properties of the water, or is of a mass and momentum that exceeds the force of adhesion and causes the debris to be propelled off the bull-nose section and onto the underlying surface.

A slightly different embodiment of the gutter cap assembly described above may not have one end attached to the fascia board 22 described above, but extends a predetermined distance up the roof surface. It is envisioned that depending upon the weather considerations, one edge of the gutter cap extending up the roof may vary, as well as its relative position to the other components. For the purposes of this description, it will be assumed the roof underlayment is covered with a traditional roofing felt material (not shown). The edge of the gutter cap may then be laid over the felt and extend upslope a predetermined distance and fastened in place by nails, roofing tar or other method. Overlaying that portion of the gutter cap on the roof underlayment may be the asphalt shingles or other roofing material. In this method, should there be a failure in the overlying asphalt shingles, moisture passing therethrough will trickle down slope onto the gutter cap flange 82 instead of penetrating to the underlayment. In event the breach occurs further up-slope, the felt or underlying course(s) of shingles or roofing material should prevent the moisture from penetrating to the underlayment.

As in the previous embodiment, the opposite edge of the gutter cap may be secured to the mounting brackets 40 described earlier. However, because of spatial differences between the location of the rain gutter and the upper surface of the roof mounted gutter cap, the profile of the nose section may not be as drastic, but not effect the flow of water into the gutter.

The roof mounted gutter cap can also be used when there is no fascia board available to mount the rain gutter 22. In those situations, the rain gutter 22 may be suspended from the overlying gutter cap by way of the mounting brackets 40 described earlier.

In each of the embodiments described above, additional improvements may be used to help facilitate the flow of water into the rain gutter such as 22 described above. For example, in a preferred embodiment of this invention, each section of gutter cap 20 may be formed from a single continuous piece of material (aluminum, galvo-aluminum, or plastic) to the desired profile and width, depending upon the particular mounting application. During the forming process, at least one or more ridges or ripples 94 may be formed in the planar or gently sloped surface 72 parallel to the length of the gutter cap or, in other words, perpendicular to the slope of the surface. In the alternative or in combination with the ripples, one or more perforations may be formed in the surface 72 to permit runoff water to pass directly into the gutter trough. The perforations are preferably positioned within the within the first third of the cap width closest to the fascia or roof drip edge. In this zone, it has been shown that run-off is substantially free of debris. Should debris be deposited on the first third of the gutter cap surface, it is of a size small enough to pass through the perforations.

FIGS. 2 through 10 illustrate one embodiment of a roll-forming machine 100 used to manufacture a continuous-piece gutter cap such as described above. To form a continuous piece gutter cap the method contemplates using a coil of aluminum or galvo-aluminum sheet material, preferably having a gauge between 1 and 30 gauge, and most preferably 18 to 26 gauge. Additionally, the roll-forming machine is adapted to manufacture continuous-piece gutter caps for both roof and fascia installation. As a result, the machine 100 will need to be able to accept stock of different widths. For example, it is contemplated the stock mentioned above have a width within the range of 8 to 24 inches, and most preferably within the range of 12 to 18 inches. Regardless of the width of the gutter cap 20, the forming process is substantially the same but for the finishing along one edge as will be described in greater detail below.

The roll-forming machine 100 comprises a series of inline stations including an intake section 102, a nose station 104, a brake station 106, and a shear station 110. Optional sections include a crease and perforation station 108. Each station is aligned and shares a common box-like frame including four parallel and spaced-apart longitudinal members. The four longitudinal embers are paired to form an upper and lower pair of longitudinal ladder assemblies 112, 114 interconnected by solid metal plates and/or bar stock 116 intended to support internal components described in greater detail below. The upper ladder assembly 112 is supported relative to ladder assembly 114 by a plurality of vertical stiles 118 as is customary. To the extent desired, the stiles 118 may also be formed from solid plate or bar stock and provide suitable substrates for particular operative devices just as members 116 briefly mentioned above.

Beginning at the left hand side of FIGS. 2-4, the machine 100 receives a sheet of stock 120 in the free end 122 of the intake station 102. The intake station 102 includes a first and a second intake roller assembly 124 and 126 cooperating to draw the stock into the machine 100. The two intake roller assemblies 124, 126 each include a lower roller 128 supported above the lower longitudinal assembly 114 by a cross member 116, and a pair of spaced-apart vertical members 130. Each lower intake roller 128 is preferably coupled to a drive system generally designated by numeral 132. To keep the stock 120 in position, and to transfer the motion of the lower intake rollers 128 to the stock 120, an upper intake roller 134 is positioned opposite, and is dependent from the upper ladder assembly 112 by a like cross member 116 and a pair of spaced-apart supports 130.

Intermediate the intake roller assemblies 124 and 126 may be a shear roller assembly 136 should it be determined to trim the stock to the proper size as it is fed into the machine 100. The shear roller assembly 136 may include an upper and a lower roller 138, 140, respectively, each slightly off-set relative to the other, and positioned so that the distance between the rollers cuts the stock 120 as it enters the machine 100. The waste material removed from the stock 120 by the shear roller assembly 136 is diverted down a separate channel 142 and is collected at a remote station. As suggested above, the shear roller assembly 136 is an optional component in one embodiment, yet in another, may be an integral aspect of the invention and to be used at the discretion of the operator. Moreover, other shear assemblies may be used other than the roller design described above. Laser and high-pressure water cutting devices may be used if desired. Alternatively, blade devices may be used such as a band saw or scissor shear system may be used at approximately the same location. The object of the different devices is of course to trim the material to the proper width before roll forming. The same or similar systems may also be employed post-roll forming to remove or trim any waste.

Subsequent to the intake station 102 may be the bull-nose station 104. The bull-nose section 104 is responsible for the bending or forming of the metal stock 120 into the bull-nose cross section 74 identified earlier. The station 104 includes two tubular or rod-shaped mandrels 144, 146 positioned a predetermined distance from one another starting downstream from the second 126 of the intake roller assemblies. The mandrels 144, 146 extend through each of the subsequent stations 106 and 108 and terminate just prior to the entry into the shear station 110 described below. The stock 120 is formed relative to the position of the mandrels 144, 146. In addition, the mandrels support the stock 120 as it moves through the machine 100.

Depending from the upper ladder assembly 112 in the bull-nose station 104 may be a plurality of rollers 148 supported by at least one, and possibly several lengths of steel or other rigid plate member 150 to position each of the rollers 148 at a predetermined depth or distance below the two mandrels 144, 146. As the stock 120 proceeds through the station, the change in elevation of the mandrels 144, 146 relative to the rollers 150 begins the formation of the bull-nose section 74. To provide the desired radius or profile, curved die-rollers 152 extend upwardly from the lower ladder assembly 114, and each configured to be placed opposite a punch-roller having a profile to be received with the die roller 152. For example, the profile of each roller 148 may be configured to mate with the profile of any die roller 152. As shown in the figures, it is contemplated at least one, preferably two, and possibly more die rollers 152 mate with a respective punch roller 148 to impart the desired radius to bull-nose section 74.

After completing the passage through the bull-nose station 104, the stock has been bent so that a desired amount of stock 120 may be available to form the respective structures along each edge 70 and 78 of the cap 20, or edges 82 and 88 of cap 80. The two angled flanges of the cap 20 ride along and are supported by the mandrels 144, 146 and the bull-nose section 74 may be engaged by a drive roller assembly 154 similar in function to the intake assemblies 124, 126. The difference between the previously described intake assembly 124, 126 and drive roller assembly 154 lies primarily in the profile of the upper roller 156. In this situation, the profile of roller 156 should closely approximate the profile of the bull-nose section so as to impart the needed amount of friction to force the stock 120 into the break station 106. The lower roller 158 may also have a matching profile to act in cooperation with roller 156 although not required. Energy may be imparted to rollers 156, 158 by the drive system 132 mentioned above through a chain drive engaging a sprocket connected to the lower roller 158.

The break station 106 bends the edges of the stock 120 to form the vertical flange 70 and the rain break 88 mentioned above. As the stock 120 travels along the mandrel rods 142, 146, the sheet of the stock 120 has a general V-shaped configuration. Positioned to engage a respective edge of the stock 120 are a first and a second break roller assembly 160, 162. Each break roller assembly 160, 162 includes a plurality of rollers cooperating with each other to progressively bend a predetermined amount of stock to a desired angle. In a preferred embodiment of the invention, substantially right-angle bends are made along the longitudinal edges of the stock 120. In order to make such bends, each edge may be engaged by two rollers 164, 166 as shown. Both rollers 164, 166 are mounted by spindles to a plate 168 which in turn is supported at the desired angle by struts or bar stock 170 depending from the upper ladder assembly 112. Roller 164 includes a chamfered surface 172 oriented at a preferred angle. Below the chamfered surface 172, the roller has a substantially cylindrical surface 174 intended to guide the stock 120. Adjacent break roller 164 may be the cooperating roller 166. In this embodiment, roller 166 may be only as thick as the cylindrical flat of roller 164 and is spaced to nearly engage the cylindrical flat 174 to support the stock 120 as the edge is partially formed by chamber 172. Should a partial bending or break be desired, a simple assembly such as just described would be sufficient. However, in the instant invention, it is desired the bends be generally perpendicular to the root portion of the stock 120. To complete the end, a second pair of rollers identified by numerals 176, 178 are also mounted to plate 168 by spindles. Roller 176 may have a composite form and include a first diameter portion 180 and a lesser diameter portion 182. The larger or first diameter portion may overlap a portion of the second roller 178 such that portion 182 may be substantially opposite and in close proximity to roller 178. In this configuration, the partially bent edge is bent the remaining distance by the overlapping portion of the rollers 176, 178. Just as in the prior description of rollers 164, 164, sufficient space may be provided between rollers 176, 178 to receive the thickness of the stock 120. If desired, springs in the form of coil or leaf springs may be used on break rollers such as 164, 166 or 176, 178 to automatically adjust to different gauge stock 120.

Downstream of the break station 106 may be the crease/perforation station 108. In the embodiments of the gutter cap mentioned above, it may be desirable to improve the capture of water runoff by improving the sheeting action of the water as it flows over surfaces 72 to direct it unto the gutter trough. To promote the sheeting action, the gutter cap 22 may have one or more parallel and cascading beads, ridges, ripples formed along the sloped surface along the length of the cap 22. These structures are roll-formed in the stock 120 by an inclined punch roller 184 extending downwardly from the upper ladder assembly 112 and positioned to engage the bottom side 186 of stock 120 forming the crown or upper surface 72 of the cap 22. A corresponding mating die roller 188 may be situated adjacent roller 184 but positioned to engage the upper surface 72, 90. As the stock 120 passes between the rollers 184, 188, the roller profiles emboss the linear cascaded features.

Adjacent the assembly for producing the ridges or linear cascading ripples 94 may be a perforation assembly generally referenced by numeral 190. The perforation assembly may be positioned downstream of the break and ridge-forming roller assemblies 160, 162 and 184, 188, but is not restricted to this particular location. The function of the perforation assembly is to produce a linear series of at least one row of oblong breaches or perforations 96 through upper surface 72, 90 intermediate the ridges 94 and the fascia flange 70 (in the case of the fascia mount version). In the embodiment where one edge is underlaying the roofing material, the perforations 96 may be formed intermediate the ridge 94 and that portion of the stock 120 first exposed or extending from beneath the roofing material.

The perforation assembly 190 includes two cooperating rollers 192, 194 mounted to spindles which in turn are fixed to a plate just as substantially all of the tools implemented in this machine 100. The roller 192 may have a profile of one or more rows of intermittent chamfered punches 196 that shear the stock at preferred locations in the first third of the gutter cap flange to create a series of water entry points that route water directly into the underlying gutter trough. The adjacent die roller 194 includes a profile intended to mate with the punches in a manner to effect the shearing action. It should be understood the perforations 96 created by this station 108 may be oriented so the openings may face up slope or down slope, depending upon the desired function. The slots may face up slope to divert run off directly unto the gutter trough or they may be oriented down slope to capture a portion of the water running over the crests, and directing run off along small rivulets over sloped upper surface 78.

Following the formation of the perforations 96, the machine 100 may complete formation of the nose section 74 and the angular orientation between the opposing edges. This is achieved by passing the partially formed cap through a series of larger diameter roller assemblies 198. For each assembly 198, the lower roller 200 may have a generally flat to concave roller surface upon which the bull-nose section 74, 92 rests. The upper roller 202 in each assembly may have a smaller radius and narrow profile to produce progressively greater bends in the bull-nose section to push the edges toward each other and ultimately to the desired angle. This may be the final stage of bending or roll-forming for the cap 20.

The final station of the machine 100 may include the shearing station 110. The shear station 110 forms the exit point for the stock 120 from the machine 100. The shear station 110 includes a die plate 204 oriented generally perpendicular to the length of the machine 100 and having an opening 206 formed therein through which the bent stock 120 passes as it exits the machine. The opening 206 has been machined so as to approximate the angled form of the cap 22 and to provide a sharp cutting edge along predetermined portions of the opening. Adjacent the die plate may be a shear plate 208 also having a profile approximating the interior of the bent cap 22. The shear plate 208 and the opening 206 are substantially aligned to permit he cap 22 to exit the machine. When the desired length of the cap 22 has exited the machine 100, hydraulic cylinders connecting the shear plate 208 to the frame 112, 114 of the machine causes the shear plate 208 to move relative to the die plate 204, shearing the stock 120. Rather than a hydraulic system to cause the shear station to operate, manually operated levers may also be used to perfect the shear.

FIG. 17 illustrates another embodiment of a gutter assembly 300 for capturing water run-off from the roof or other sloping structure while directing debris onto the underlying surface. As shown in the figure, gutter assembly 300 includes a gutter trough 302 mounted to a fascia board or similar vertical support 304 located generally below a drip edge of a sloping surface, in this case a roof 306. Disposed above the gutter trough 302 is a unique gutter cap 308 wherein one edge may be defined by an upwardly extending flange 310 designed to be received behind a flange of the drip edge 312 or other shield adjacent the fascia board. Extending from the flange 310 in a direction away from the fascia board 304 is the upper surface 312 oriented so as to slope downwardly at a predetermined angle relative to the fascia. The degree of slope has not yet been determined to be a critical element so long as it is sufficient to direct the flow of water down gradient away from the fascia. For example, it is contemplated that the slope of surface 312 be less than forty-five degrees but greater than zero degrees, preferably less than fifteen degrees but greater than one degree, and most preferably less than ten degrees but greater than two degrees.

To help maximize the diversion of water into the gutter trough 302, periodic perforations or slots 314 may be formed in the upper surface 312 such that the openings face either up slope or down lope as described earlier. It has been found that if the gutter cap is to include such slots, the location may be best within the first one-third of the gutter cap width as measured relative to the fascia board 304. It has been observed that water run-off within this zone onto the gutter cap contains less detritus and debris than any point down slope, and thus less likely to interfere with the flow of water into the perforations.

Down slope of the first one-third portion of the gutter cap width, additional structures may be formed to help increase the amount of water captured within the trough while minimizing the capture of unwanted debris. For example, it may be contemplated that at least one or more beads, ridges, or grooves 316 may be formed in the upper surface 312. These structures may be formed periodically or continually along the length of the gutter cap 308. The function of these structures is to provide temporary dams or obstacles to reduce the current speed as the water flows over the surface 312 for reasons that will become more apparent below.

The downwardly sloping surface 312 of the gutter cap transitions into what has been described above as the nose or bull-nose section, designated by numeral 318 in the Figure. However, in this embodiment, the nose section 318 is not formed in a continuous radiused structure as described above. Rather, the nose section may be more aptly described as substantially rectangular or angular, formed by a tightly radiused first-bend 320, followed by a substantially planar intermediate section 322, then a second tightly radiused second-bend 324. In a preferred embodiment, each of the tightly-radiused bends 322 and 324 are such that they do not disrupt the relatively smooth surface characteristics of the metal or finish that may cause to disrupt the flow of water over that portion of the cap. For example, it is contemplated the radius for making such bends may be less than one-quarter of inch, but greater than one-thirty-second of an inch. The object here is to avoid a truly sharp angular change in the profile, but rather an arcuate profile within a small distance. In this manner, the molecular attraction (adhesion) of the flowing water with the surface of the gutter cap can be maintained within a given flow rate to direct the water into the underlying gutter trough, yet provide a very appealing finish to the edge of the gutter cap that complements most gutter trough profiles.

As in the previous embodiments, the opposite edge 326 extends back toward the fascia board 304 and terminates above the gutter trough 302 such that water flowing along the upper surface 312 and around radius 320, over surface 322, and around radius 324 flows into the gutter trough. The edge 326 of the gutter cap 308 may also contain a break flange similar to that described above to break the adhesion of the water and increase the turbulence to maintain any detritus in suspension so that it may ultimately flow to a downspout.

The description of the different aspects of the invention provided above is considered that of a limited number of a wide range of variations that can be implemented. Other modifications or configurations will occur to those skilled in the art and to those who use and/or make the invention. Thus, it is understood the foregoing description and structure shown in the drawing figures are provided merely for illustrative purposes and are not intended to limit the scope of the invention claimed herein or in any subsequent related application. 

1. A roll-forming machine for making a substantially continuous length of a cap for a rain gutter, comprising: an intake station at one end of the roll-forming machine for drawing a predetermined length of material into the roll-forming machine; a first station following said intake station for forming a nose-section of the cap; at least one break station following said intake station for creating a first flange along at least one edge of the cap; and a shear station at an opposite end of the roll-forming machine for cutting the cap to a predetermined length.
 2. The roll-forming machine as defined in claim 1, further comprising a bead forming station for forming at least one bead of predetermined length along an upper surface of the cap.
 3. The roll-forming machine as defined in claim 1, further comprising a shear forming station for forming at least one slot of predetermined length at predetermined locations along an upper surface of the cap.
 4. The roll-forming machine as defined in claim 1, further comprising: a first break station for forming a break along an opposite edge of the cap; a roller assembly for forming an upper surface connected to and extending away from said first flange for slowing a flow of run-off, dispersing the run-off over the upper surface, and to promote adhesion between the run-off and the upper surface of the cap; and a station for forming an angular profile along an edge of said upper surface opposite that of said first flange for diverting the run-off substantially around said nose portion and into the rain gutter while preventing detritus of predetermined size from entering into the rain gutter.
 5. The roll-forming machine as defined in claim 1, further comprising at least one roller assembly for forming one of a bead and a trough in a surface of the cap for reducing a flow rate of the run-off over said surface.
 6. The roll-forming machine as defined in claim 1, further comprising an assembly for forming a plurality of slots in a surface of the cap and a direct route for run-off to enter into the gutter.
 7. The roll-forming machine as defined in claim 1, further comprising a roller assembly for forming a water break along a lower edge of the cap.
 8. A method for roll-forming a rain gutter cap, comprising the steps of: providing a predetermined length of roll-forming material; feeding an end of said roll-forming material into one end of a roll-forming machine; shearing the roll-forming material to width as the roll-forming material enters into the roll-forming machine; forming an angular nose section by passing the roll-forming material between at least two rollers; forming at least one break section along one edge of the roll-forming material; forming at least one bead of predetermined size intermediate the nose section and the at least one break; and cutting the roll-forming material to a predetermined length.
 9. The method as defined in claim 8, further comprising: forming a gently sloped upper surface intermediate the nose section and the at least one break section to be positioned beneath a roofing surface and another portion extending away from the roofing surface; creating at least one row of perforations intermediate the bead and the edge of the roll-forming material; and forming an opposite edge of the roll-forming material to extend back under the gently sloped upper surface down to be disposed at least partially above the gutter.
 10. The method as defined in claim 9, further comprising attaching the gutter to a fascia board of a building a predetermined distance below a drip edge of a roof surface.
 11. The method as defined in claim 10, further comprising mounting a bracket having one end engaging an outer most edge of the gutter, and an opposite end engaging an opposite wall of the gutter.
 12. The method as defined in claim 11, further comprising fixing at least one fastener through the mounting bracket and into the fascia board to hold the gutter in position.
 13. A rain gutter assembly, comprising: a flange received beneath a drip edge attached to an edge of a roof structure; and a downwardly sloping surface extending away from said flange to a nose section disposed approximately above an outer edge of the gutter, the nose having a radius less than an angular rate of acceleration experienced by a fluid flowing over said downwardly sloping surface so as to disturb a substantially linear flow of the fluid over said sloping surface.
 14. The gutter assembly as defined in claim 13, further comprising an edge of the gutter cap opposite said flange extending back under said downwardly sloping surface and terminating above the gutter to divert the fluid flowing along said downwardly sloping surface into said trough, said opposite edge fixed by a mounting bracket for attaching said trough below said drip edge.
 15. A gutter assembly defined in claim 14, further comprising a plurality of mounting brackets disposed within the gutter, each mounting bracket including a plurality of step-like structures, one of which engages the outmost edge of the rain gutter and an opposite end engaging an opposite side of the gutter, and adapted to receive at least one fastener there through to attach the gutter to the fascia.
 16. The gutter assembly as defined in claim 15, further comprising a gutter cap having a sloped upper-surface adapted to be at least partially received under at least one layer of roofing material such that runoff from the roofing material flows onto the gutter cap; an opposite edge of the gutter cap directed back under said sloped surface to form a nose of predetermined profile; an end extending back under said sloped surface and terminating above said rain gutter; whereby said opposite edge of said rain gutter cap terminating above said rain gutter trough and fixed relative to said rain gutter by a mounting bracket. 